DE202017107592U1 - Charging station for flashlights - Google Patents

Abstract

Charging station with a charging contact device (20) and a Akkumumulatorbetriebenen flashlight (10) arranged transversely to the flashlight longitudinal axis and mutually insulated charging contacts (14, 15) on the flashlight housing jacket electrically conductive when recharging the batteries to charging pads (28, 29) of the charging contact device (20) abutment, characterized in that each of the two charging contacts (14, 15) on the flashlight housing over an arc of <180 ° extends, that the charging contact means (20) has a base body (21) with a support surface (25) and two side body (23, 24) having surfaces on each of which charging contact points (28, 29) are arranged and that the side bodies (23, 24) each comprise a magnet (27), by the magnetic force field, the flashlight (10) in the position when recharging the batteries is positionally and functionally secure fixable.

Description

The invention relates to a charging station with a charging contact device and a Akkumumulatorbetriebenen flashlight arranged transversely to the flashlight longitudinal axis and mutually insulated charging contacts on the flashlight housing jacket, which rest electrically charged during recharging of the batteries at charging pads of the charging contact.

Battery operated flashlights are indispensable in the event of a power outage or a lack of fixed line connection. The active life of a flashlight is limited by the battery capacity. A significant improvement in service life could be achieved by using light-emitting diodes instead of the incandescent lamp, because the LED power consumption is much lower.

With frequent use, the use of rechargeable batteries (accumulators) makes sense. One known in the prior art possibility is to remove the batteries whose capacity is exhausted from the flashlight and to use these batteries in a separate battery charger and left there to reach the maximum charge capacity. During this time, the flashlight is inoperable or must be powered by another battery pack or battery. In many accumulator operated devices, in particular cell phones, the accumulator may remain in the device during recharging, provided that this device has a male contact, via which the device is connectable to a charger connected to a stationary power source.

In addition, charging stations are known. In the DE 297 21 015 U1 the charging station has a holder for a accumulator-operated handset, in or on the handset is on or plugged, also a power supply plug, which can be electrically connected by means of electrical contacts with the arranged in the holder handset. The handset should be able to be fixed in different angular positions to the insertion or Aufsteckrichtung on the holder, these positions are associated with electrical contacts.

In the US 4,092,580 B1 a charging station for a flashlight is described, in which the flashlight can be detachably inserted via a clamping device in a holding device. However, this charging station has the disadvantage that handsets that need to be removed quickly from the charging station, must first be separated from this. If this must be done quickly in the professional area of use, for example, the police or fire, there is a risk that existing connectors can be easily damaged.

The EP 2 216 871 therefore proposes a charging station with a charging contact device and with an accumulator-operated flashlight, in which the flashlight has a contact device and at least partially a ferromagnetic material. The charging contact device has a magnet which can be brought into operative connection with the ferromagnetic material such that the charging contact device of the charging station and the contact device of the flashlight can be brought into contact correspondingly. The charging station is arranged on a holder such that the flashlight is held in a vertically arranged holder by the magnet in the state of charge. However, such a charging station requires a wall mounting of the bracket in a vertical position, which is not always given. A location-flexible use of such a charging station is not possible. Another disadvantage of the charging station is that the holding force must be applied solely by a magnet which must be large enough to hold the weight of the flashlight. Inadvertent firing of the flashlight may cause the lamp to come off the bracket and fall to the ground.

In the DE 10 2014 113 932 A1 a charging station is described with a battery-operated electric flashlight, wherein the charging station comprises a charging tray and a charging contact device and at least two charging contacts, which are electrically connected to other electronics. The charging contacts are like a pin over the surface of the charging tray. The flashlight describes an end face in which an electrical actuator which projects beyond the end face and a contact device are arranged, which have at least two electrical contact surfaces, wherein the contact surfaces are arranged around the electrical actuator in an annular and axisymmetric orientation and isolated by an insulating element. The flashlight is releasably adjustable with its end face in the charging station, in which case the charging contact of the charging station and the contact device of the flashlight are brought into corresponding contact, but a distance between the end face of the flashlight and the surface of the charging lamp is maintained, which is greater than that Projection of the actuating element over the end face. Also in this device, the flashlight must be used vertically. In addition, the charging contacts must be spring loaded to ensure a sufficient contact closure, which is indispensable for recharging.

In the DE 20 2016 103 327 U1 a flashlight with charging station is proposed, in which a number of charging contacts on the housing outer casing are to be spaced from each other, so that the contacting of the charging contacts is transverse to the housing longitudinal direction. The mechanical support is a spring-based clamping bracket, in which the flashlight is held in two places, namely near the head and near the foot in the charging station.

It is an object of the present invention to provide a charging station with a charging contact device and a Akkumumulatorbetriebenen flashlight, which are easy to handle and structurally simple.

This object is achieved by the charging station according to claim 1, which is inventively characterized in that each of the two charging contacts on the flashlight housing over a circular arc of <180 ° extends, that the charging contact means has a base body with a support surface and two side body with surfaces on each of which charging contact points are arranged and that the side bodies each contain a magnet, by the magnetic force field, the flashlight in the position when recharging the accumulators positionally and functionally fixed.

The particular advantage of this charging station is that the flashlight at least substantially in a horizontal position in the charging station can be inserted, the spatial position of the flashlight on the one hand by the side body (in the transverse direction) and by each present in each side body magnet (in the longitudinal direction ) is clearly defined. For this fixation no springs, clamp body or other wear-sensitive parts are needed. The charging station is not limited to a fixed attachment, but can also be carried and used in motor vehicles, if the already necessary transformer of the charging station is tuned to the board supply voltage. The existing magnet provides sufficient force to ensure contact closure during charging. Nevertheless, the lamp can be easily removed from the charging device, without a preferential removal direction is observed or other clamp body must be solved.

Further developments of the invention are described in the subclaims.

Thus, the side bodies are preferably arranged vertically to the support surface and have a height which is greater than the flashlight radius in the region in which the charging contacts of the flashlight are arranged. This measure allows lateral stabilization of the flashlight during charging without the possible removal directions for the flashlight from the charging bracket are unnecessarily limited.

According to another preferred embodiment, the flashlight has a lamp head with a larger diameter than the diameter of the rest of the lamp housing, wherein the diameter changes abruptly. The charging contacts of the flashlight are arranged on the annular diameter extension and are - due to the magnetic force - on an end face of the side body during the recharging process. In other words, the flashlight has a "heel-shaped" extension of the lamp body, through which an annular surface is created, which abuts the end face of each side body during the recharging process. These end faces thus offer the "stop surfaces" for the lamp head end facing the rest of the lamp housing. As a result, the longitudinal axial position of the flashlight during recharging is clearly defined. In addition, the base surface may have a trough-shaped depression in a front region whose radius is at least as great as the radius of the pocket lamp head. This reduction serves the further unambiguous position definition of the flashlight in the charging station during recharging.

The part-circular contact points on the lamp housing are preferably arranged mirror-symmetrically to a cross-sectional plane in which a switch for switching on and off of the lamp is arranged on the lamp housing jacket.

In the selected charging contact two charging contacts on the flashlight housing, which extend over a circular arc of <180 °. The angle below 180 ° is due to the fact that the charging contacts must be isolated from each other, whereby the 180 ° below the angle can be explained. Preferably, the first insulator is selected approximately at the level of the jacket area in which the switch of the flashlight is located, whereas the other insulator is arranged diametrically opposite. This choice also makes it immediately obvious to the user under which "rotation angle" he must insert the lamp for recharging; in the simplest case, he just has to make sure that the on / off switch is moved to an upper position.

According to a further embodiment, the part-circular contact points on the lamp housing made of ferromagnetic material, with the in the side bodies arranged permanent magnets can interact.

Further details of the invention are shown in the drawings. Show it:

1 a perspective view of a charging station with a charging contact device and a flashlight,

2 a perspective view of the charging station with a partially sectioned view of a side body,

3 the charging station with flashlight and

4 the charging contact in a perspective, partial sectional view.

The in the 1 to 4 illustrated charging station sets from a flashlight 10 and a charging contact device 20 together. The flashlight has a lamp head 11 , which is cylindrical in shape and on its shell side a switch 12 has to turn on and off the flashlight. In the lamp head, the light source, namely an arranged on a board LED including power supply and at least one lens which is arranged to change the light cone relative to the longitudinal axis axially movable and the one via the switch 12 has operable adjustment mechanism. The lamp head 11 is stepped towards the flashlight housing 13 durchmesserverbreitert. In the case 13 the accumulators are held. At the transition of the lamp head 11 to the lamp housing 13 are two charging contacts 14 . 15 arranged, which extend almost semicircular over a circular arc of nearly 180 °. In each case between the partial ring ends of the charging contacts 14 . 15 are insulators 16 and 17 intended. The charging contact device 20 has a base body 21 with a connection socket 22 for plugging in a charging cable connected to a suitable transformer. The charging station also has two vertically arranged side body 23 . 24 ,

How out 4 shows, the base body has a support surface 25 and a trough-shaped recess 26 with a radius that is at least as large as the radius of the flashlight head 11 ; Ideally, the radii are about the same size. In each of the side bodies 23 and 24 is a permanent magnet toward a front end 27 contain. The side bodies 23 and 24 have a height that is less than the diameter of the lamp housing part 13 is, at least the height is greater than the radius. The side bodies 23 and 24 are each rounded front and back. The rounded edges 28 and 29 serve as charging points at which to recharge the batteries, the charging contacts 14 . 15 touching and electrically conductive abut. The power supply is a spring clip 30 in each side body 23 and 24 arranged and with the connection socket 22 connected is.

Shall the accumulators of the flashlight 10 be charged, so the lamp housing 13 between the side bodies 23 and 24 the operator merely has to take care that the switch 12 is above, that is, for example, in 1 and 2 position shown assumes. Minor angular shifts are insignificant because it only matters that the charging contact 15 with the contact surface 28 and the charging contact 14 with the contact surface 29 comes into contact. The trough-shaped recess serves as a centering aid 26 whose curvature is approximately the curvature of the lamp head 11 equivalent. The loading position is always reproducible when the contact surfaces 14 and 15 to the contact surfaces 28 and 29 be brought as a stop to the plant. The stability of this loading position is determined by the permanent magnet 27 , which is contained in each side body, guaranteed because the charging contacts 14 and 15 Made of ferromagnetic material, by the magnet 27 is attracted.

The charging device can be parked anywhere, the footprint does not even have to lie horizontally, because the two permanent magnets 27 in the side bodies 23 and 24 apply the necessary holding power. Upon completion of charging or, if the battery has reached a minimum state of charge, during charging, the flashlight may be on the flashlight housing 13 or lamp head 11 recorded and easily removed. In this case, neither clamp closures are to be solved nor is special care when removing the lamp from the charging station needed. The charging station is thus largely insusceptible to mechanical damage and easy to handle. Short-circuit contacts are made by choosing the part-circular charging contacts 14 and 15 and the insulators 16 . 17 effectively prevented.

LIST OF REFERENCE NUMBERS

10

flashlight

11

lamp head

12

switch

13

flashlight casing

14, 15

charging contacts

16, 17

insulators

20

Charging contact device

21

base body

22

socket

23, 24

side body

25

bearing surface

26

trough-shaped recess

27

permanent magnet

28, 29

Charging contact points

30

spring clip

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 29721015 U1 [0004]
• US 4092580 B1 [0005]
• EP 2216871 [0006]
• DE 102014113932 A1 [0007]
• DE 202016103327 U1 [0008]

Claims (6)

Charging station with a charging contact device ( 20 ) and an accumulator-operated flashlight ( 10 ) arranged transversely to the flashlight longitudinal axis and mutually insulated charging contacts ( 14 . 15 ) on the flashlight casing jacket used in recharging the rechargeable batteries at charging points ( 28 . 29 ) of the charging contact device ( 20 ) electrically conductively, characterized in that each of the two charging contacts ( 14 . 15 ) extends on the flashlight housing over a circular arc of <180 ° that the charging contact device ( 20 ) a base body ( 21 ) with a bearing surface ( 25 ) as well as two side bodies ( 23 . 24 ) having surfaces at each of which charging pads ( 28 . 29 ) are arranged and that the side body ( 23 . 24 ) each a magnet ( 27 ), through whose magnetic force field the flashlight ( 10 ) in the position when recharging the accumulators positionally and functionally reliable fixable. Charging station according to claim 1, characterized in that the side bodies ( 23 . 24 ) vertical to the support surface ( 25 ) are arranged and have a height that is greater than the flashlight radius in the area in which the charging contacts ( 14 . 15 ) of the flashlight ( 10 ) are arranged. Charging station according to claim 1 or 2, characterized in that the flashlight ( 10 ) a lamp head ( 11 ) with a larger diameter than the diameter of the rest of the lamp housing ( 13 ) has that the diameter changes abruptly and that the charging contacts ( 14 . 15 ) of the flashlight ( 10 ) are arranged on the annular diameter extension and - due to the magnetic force - at an end face ( 28 . 29 ) the side body ( 23 . 24 ) during the recharging process. Charging station according to one of claims 1 to 3, characterized in that the base surface ( 25 ) in a front region a trough-shaped depression ( 26 ), whose radius is at least as large as the radius of the flashlight head. Charging station according to one of claims 1 to 4, characterized in that the part-circular charging contact points ( 14 . 15 ) on the lamp housing ( 11 ) are arranged mirror-symmetrically to a cross-sectional plane in which a switch ( 12 ) for switching the lamp on and off ( 10 ) is arranged on the lamp housing jacket. Charging station according to one of claims 1 to 5, characterized in that the part-circular contact points ( 13 . 14 ) on the lamp housing ( 10 ) consist of ferromagnetic material and in the side bodies ( 23 . 24 ) arranged magnets ( 27 ) Are permanent magnets.

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